Title :
Robustness of LDMOS power transistors in SOI-BCD processes and derivation of design rules using thermal simulation
Author :
Krabbenborg, Benno H. ; Van der Pol, Jacob A.
Author_Institution :
Philips Semicond., Nijmegen, Netherlands
Abstract :
In SOI devices, the buried oxide alters the thermal impedance compared to a bulk device and a gives a higher temperature rise that influences the robustness of the device. In this paper, power LDMOS transistors (with integrated temperature sensors) in an SOI-process are evaluated with Safe Operating Area (SOA) measurements. The failure mechanism based on triggering of the parasitic bipolar, is discussed with the aid of dynamic temperature measurements. The results show that the failure energy can be related to a critical temperature rise that depends on VDS. Consequently, the thermal impedance and VDS fully determine the failure energy. Hence, 3D thermal simulation can be used as a tool for dimensioning power transistors. A comparison of SOI-DMOS with bulk-DMOS and bulk-Bipolar shows that in SOI it is still very well possible to create power devices with a good SOA
Keywords :
buried layers; power MOSFET; silicon-on-insulator; 3D thermal simulation; LDMOS power transistor; SOI-BCD process; buried oxide; critical temperature rise; design rule; dynamic temperature measurement; failure energy; integrated temperature sensor; parasitic bipolar transistor; robustness; safe operating area; thermal impedance; Area measurement; Failure analysis; Impedance; Power measurement; Power transistors; Robustness; Semiconductor optical amplifiers; Temperature dependence; Temperature measurement; Temperature sensors;
Conference_Titel :
Power Semiconductor Devices and ICs, 2001. ISPSD '01. Proceedings of the 13th International Symposium on
Conference_Location :
Osaka
Print_ISBN :
4-88686-056-7
DOI :
10.1109/ISPSD.2001.934579
